Image courtesy of Argonne National Laboratory
Tuning the ATTA magneto-optic atom trap at Argonne National laboratory.
The Office of Nuclear Physics funds a community of scientists to do basic nuclear physics research that seeks to uncover the fundamental nature of matter. As a consequence of this basic research, many ideas and instruments (funded through various sources) have found their way into many different areas in public life as well as in other government programs. This highlight is an example of such a "spinoff"
A specialized magneto-optical atom trap called Atom Trap Trace Analysis (ATTA) allows scientists to detect single atoms of Krypton (Argon) at and below the part-per-trillion (part-per-quadrillion) level. Detecting the rare krypton-81 isotope (81Kr) with this unprecedented analytic sensitivity helps reveal the fate of water in ancient aquifers. Knowing how long water has been underground helps researchers understand how fast aquifers are recharged by surface water and how fast they move, leading to more accurate geological models.
Rare isotope 81,85Kr-, 39Ar-dating opens up new opportunities in the Earth sciences including practical water resource management, ocean circulations, and the study of our planet’s ancient climate.
A state-of-the-art Atom Trap Trace Analysis (ATTA) instrument has been developed by a team of physicists working at Argonne National Laboratory working in collaboration with Earth scientists and other supporting agencies in the U.S. and worldwide. The ages of groundwater, ranging from 200,000 to 1,000,000 years old, in the Nubian Aquifer underneath the Eastern Sahara Desert, the Great Artesian Basin of Australia, and the Guarani Aquifer of South America have been measured. These results reveal hydrologic behavior of huge aquifers, with important implications for climate history and water resource management. Application of rare isotope 81,85Kr-, 39Ar-dating using ATTA in other areas of Earth sciences now appears feasible. The radioisotope 85Kr is routinely measured as a residence-time tracer for young (<60 years) shallow groundwaters that are most susceptible to contamination. When combined with other tracers, 85Kr measurements will improve the quality and reliability of groundwater flow and vulnerability assessments. A systematic survey of 39Ar throughout the oceans could fill major gaps in our knowledge of deep ocean circulation and mixing, and allow better predictions of oceanic sequestration of atmospheric CO2. Polar ice cores have been used to reconstruct Earth’s past climate and atmospheric composition as far back as 800,000 years in time. 81Kr could potentially be used for dating of old ice with ages ranging from 100,000 – 1,500,000 years. In volcanic and geothermal systems, the analysis of crustal fluid samples for noble radionuclides 39Ar, 81Kr, and 85Kr could provide information on the origin, evolution, and migration of crustal fluids.
Dr. Zheng-Tian Lu
Argonne National Laboratory
Office of Science Nuclear Physics (NP) program
Sturchio, N. C. “One million year old groundwater in the Sahara revealed by krypton-81 and chlorine-36.” Geophys. Res. Lett. 31 L05503 (2004). [DOI: 10.1029/2003GL019234]
University, DOE Laboratory
Technology Impact, Collaborations, Non-DOE Interagency Collaboration, International Collaboration